Assume that $A$ is  a unital $C^{*}$ algebra. Is there a subvector space $Y\subset A$ of finite codimension which  does not contain any invertible element?

Let $n(A)$ be the infimum of such codimensions. For example  $n(A)=1$ if $A$ is commutative. Or $n(M_{n}(\mathbb{C}))=n$.

For a commutative $A$, is it true to say $n(A\otimes M_{n}(\mathbb{C}))=n\times 1=n$? More generaly, can one express $n(A\otimes B)$ in term of $n(A)$ and $n(B)$? 

**Edit:**  According to the  comments on this post, we ask:"What is  an example of  a  simple  $C^{*}$ algebra $A$ for which $n(A)$ is  finite? Of course for such algebra, $n(A)\neq 1$.


**Note:** This question is somehow a reverse question to the following famous problem:

What is the maximim possible dimension for those subvector space of $M_{n}(\mathbb{R})$ which consist only invertible matrices(except zero matrix). For what valuse of $n$ the sharp dimension would occure?